Systems and methods for visualizing patient and telepresence device statistics in a healthcare network

ABSTRACT

Disclosed herein are various embodiments of systems and methods for visualizing, analyzing, and managing telepresence devices operating in a telepresence network of healthcare facilities. A user may selectively view a global view of all telepresence devices, telepresence devices within a particular region, the details of a particular telepresence device, and/or the details of a particular healthcare facility. At one viewing level, a user may view a plan view map of a healthcare facility and visualize the navigational history of a telepresence device. At another viewing level, a user may view a plan view map of a healthcare facility and visualize telemetry data of a patient associated with a selected room. At another viewing level, a user may selectively view various graphical representations of telepresence device statistics and usage information with respect to health ratings for each of a plurality of patients.

TECHNICAL FIELD

This disclosure relates to managing telepresence devices in healthcarenetworks. More specifically, this disclosure provides variousvisualization and management systems for use with telepresence devices,healthcare networks, and associated information.

BRIEF DESCRIPTION OF THE DRAWINGS

Non-limiting and non-exhaustive embodiments of the disclosure aredescribed herein, including various embodiments of the disclosureillustrated in the figures listed below.

FIG. 1 illustrates a viewing level including a geographicalrepresentation of the world, shortcut links to various geographicallocations, selectable icons associated with various device types, anavigation input panel, and selectable overlays.

FIG. 2 illustrates a viewing level of a geographical representation ofthe United States with a population density overlay.

FIG. 3 illustrates a shortcut menu configured to allow for directnavigation to various locations within a geographical representation.

FIGS. 4A and 4B illustrate context-based detail request menus providingaccess to specific details based on the type of telepresence deviceand/or type of healthcare facility.

FIG. 5 illustrates a viewing level including a session viewer formonitoring sessions and telepresence devices during a selected timeperiod.

FIG. 6 illustrates a detailed session viewer for monitoring a locationof a telepresence device at various time periods on a geographicalrepresentation, the geographical representation including an overlay ofwireless communication availability.

FIGS. 7A and 7B illustrate viewing levels including the location andinterconnections of medical facilities in a healthcare network on ageographical representation.

FIG. 8 illustrates a viewing level providing stroke informationassociated with a healthcare network on a geographical representation.

FIG. 9 illustrates a viewing level including a dashboard of detailedinformation associated with one or more telepresence devices.

FIG. 10 illustrates a viewing level including session details for aparticular telepresence device.

FIG. 11 illustrates a viewing level including stroke informationassociated with a healthcare network provided via a StrokeRESPONDapplication.

FIG. 12 illustrates a viewing level showing navigational paths of atelepresence device on a plan map for a selected time period.

FIG. 13 illustrates a viewing level showing telemetry data for a patientas a pop-up window on a plan map in a selected room of a healthcarefacility.

FIG. 14 illustrates a table of patients, outcome ratings, andtelepresence device statistics associated with each of the patients.

FIG. 15 illustrates a coordinate system including selected graphs ofpatient outcome ratings and various telepresence device statistics.

FIG. 16 illustrates a coordinate system including graphs of patientoutcome ratings, a number of visits per day, and a number of stethoscopeuses.

FIG. 17 illustrates a coordinate system including graphs of patientoutcome ratings, a number of visits per day, and a number of stethoscopeuses, where the patients included on the coordinate system are filteredbased on a specific health condition.

FIG. 18A illustrates a graph of patient outcome ratings and an amount oftime a camera of a telepresence device is zoomed greater than 50%.

FIG. 18B illustrates a graph of patient outcome ratings and an amount oftime a camera of a telepresence device is zoomed greater than 50%, wherethe patients included on the coordinate system are filtered to includeonly those with a neurological condition.

FIG. 19 illustrates a graph of patient outcome ratings and selectedtelepresence device statistics, including a selection of patientsfiltered by physician contrasted with similar telepresence devicestatistics for all of the patients (unfiltered).

FIG. 20 illustrates a graph of patient outcome ratings and selectedtelepresence device statistics, including a selection of patientsfiltered by room number contrasted with similar telepresence devicestatistics for all of the patients (unfiltered).

FIG. 21 illustrates a functional block diagram of a computer systemincluding various modules for a telepresence network visualization andmanagement system.

The described features, structures, and/or characteristics of thesystems and methods described herein may be combined in any suitablemanner in one or more alternative embodiments, and may differ from theillustrated embodiments.

DETAILED DESCRIPTION

The present disclosure provides various systems and methods forvisualizing and managing telepresence devices within healthcare networksand facilities. Using the presently described visualization andmanagement tool, users may more efficiently visualize, analyze, andactively manage various aspects of a telepresence healthcare network. Insome embodiments, a user may view a geographical representation of therelative location of each of a plurality of telepresence devices in atelepresence network.

Healthcare facilities may include telemedicine technologies, such astelepresence devices in a telepresence network, that allow remotehealthcare practitioners to provide services to patients and/or otherhealthcare practitioners in remote locations. For example, a remotemedical professional may be a neurologist practicing in a major hospitalwho may, via telepresence devices, provide services and consultations topatients and other medical professionals in hospitals located in ruralareas that may otherwise not have a neurologist on staff.

The telepresence devices may operate as part of a telepresence networkassociated with one or more healthcare networks. Each healthcare networkmay include one or more healthcare facilities (e.g., hospitals,rehabilitation facilities, and long-term care facilities) that each haveone or more telepresence devices. Types of telepresence devices include,but are not limited to, remote telepresence devices, mobile telepresenceunits, and/or control stations. For example, a remote telepresencedevice may include a telepresence robot configured to move within amedical facility and provide a means for a remote practitioner toperform remote consultations.

A visualization and management system for telepresence devices may beconfigured to display a first viewing level that includes a geographicalrepresentation of the location of various telepresence devices. Theviewing level may include all telepresence devices, those withinpredefined geographical boundaries, those associated with a particularhealthcare network, or those associated with a particular healthcarefacility. The telepresence devices and/or healthcare facilities may alsobe displayed as hub devices/facilities and spoke devices/facilities. Thevarious interconnections between the hubs and spokes may be selectivelydisplayed.

A navigation control panel may allow a user to navigate within thegeographical representation. For example, the navigation panel may allowfor panning, tilting, scrolling, compass alignments, and/or othernavigational options. Additionally, the field of view may be dynamicallymodified based on a user's selection. For example, the field of view maybe controlled by a zooming panel or icon, or alternatively may bedynamically adjusted based on other navigational or icon selections. Theinformation associated with the displayed telepresence devices and/orhealthcare facilities may be limited or expanded based on the number oftelepresence devices and/or healthcare facilities currently displayed inthe selected field of view. In some embodiments, shortcuts may allow auser to quickly navigate to a specific geographical location, to aspecific medical facility, to a specific medical network, and/or to aspecific telepresence device.

The first viewing level may include various icons, panels, buttons,and/or other selectable options configured to allow a user to select oneor more alternative viewing levels. For example, a device detail requestmodule may allow a user to submit a detail request in order to viewdetailed information associated with one or more telepresence devices,healthcare facilities, and/or healthcare practitioners shown on thegeographical representation. A user may request additional details byselecting a particular telepresence device and/or healthcare facility.In some embodiments, additional details may be presented when a usermouses over a device/facility. The mouse-over may cause a pop-up overlayto appear displaying additional details associated with thedevice/facility. The details associated with one or more telepresencedevices may include the connection strength, the number of activesessions, a history of technical problems, a history of sessionactivity, shipping information associated with a telepresence device,information associated with a software update, information associatedwith a firmware update, a serial number, a model number, a batterylevel, a date the telepresence device last reported, a time thetelepresence device last reported, historical session data, a registeredperipheral, a licensed application, a total utilization time, an averagesession duration, a duration of a particular session, a start time of aparticular session, an end time of a particular session, a Quality ofService (QoS) for one or more sessions, a current available bandwidth, abandwidth availability with respect to time, a current location of atelepresence device, and historical locations of a telepresence devicewith respect to time.

Similarly, the details associated with one or more healthcare facilitiesmay include a number of active sessions, a number of active telepresencedevices, a connection strength of telepresence devices, a connectionbetween two or more telepresence devices, a location of a telepresencedevice, information from a StrokeRESPOND application, a door-to-needletime, a door-to-balloon time, t-PA contraindication and warninginformation, a healthcare practitioner response time, and a call centerresponse time.

Additionally, details associated with a particular telepresence device,healthcare facility, healthcare network, and/or healthcare practitionermay include one or more connection rules. For example, connection rulesmay define where, when, and how a healthcare facility, healthcarenetwork, and/or healthcare practitioner may access, view, monitor,and/or control a particular telepresence device or set of telepresencedevices. The connection rules may also define who is granted access andwhat devices they can view. In some embodiments, a viewing leveldisplaying one or more connection rules may allow a user to manageand/or configure the various connection rules between devices,facilities, and/or practitioners. In one embodiment, connection rulesmay be managed using drag-and-drop actions between devices, facilities,and/or practitioners.

Some of the viewing levels may include geographical representationsconstrained by particular geographical boundaries, the extent of ahealthcare network, or the location of associated telepresence devices.Some of the viewing levels may include selectable overlays configured tooverlay information on the geographical representations. Accordingly, auser may apply an informational overlay to a geographical representationthat includes various healthcare facilities and/or telepresence devices.

Examples of overlays include, but are not limited to, a populationdensity, a stroke frequency, an adoption rate of a software update, anadoption rate of a firmware update, a frequency of a particular medicalcondition, a frequency of a particular technical difficulty, an averageage of the population, an average age of patients, socioeconomicconditions, an availability of wireless communications, a relativelocation of medical practitioners, active sessions, a data connectionstrength, and a relative location of support technicians. Theinformational overlay may be overlaid on the geographical representationas a heat map, as graphics, as pictures, as icons, as numbers, and/or astext.

In some embodiments, the informational overlay may be overlaid on theentire geographical representation. In other embodiments, theinformational overlay may be overlaid on a portion of the geographicalrepresentation. For example, the informational overlay may only beoverlaid on the portion of a geographical representation thatcorresponds to a geographical area serviced by a particular healthcarenetwork, hospital, hub hospital, spoke hospital, telepresence device,support technician, and/or medical practitioner.

In some embodiments, a viewing level may include a geographicalrepresentation displaying the relative location of various telepresencedevices. The viewing level may include various selectable device iconsthat each correspond to a particular type of telepresence device. Thedevice icons may be used to toggle between displaying and not displayingthe associated type of telepresence device. Accordingly, a user maytoggle the device icons in order to view all of the control stations,but not the mobile telepresence units or the remote telepresence robots.Within the same viewing level, the user may toggle the device icons toview the remote telepresence robots and/or the mobile telepresenceunits, but not the control stations. Additional device icons may furtherdifferentiate between device types, models, vintages, activetelepresence devices, inactive telepresence devices, and/or othercharacteristics of the various telepresence devices.

The visualization and management of telepresence networks may allowhealthcare facilities, healthcare networks, healthcare practitioners,technical support personnel, and/or other users to improve patient care,provide enhanced telepresence services, reduce the costs associated withtelepresence consultations, and/or otherwise improve existingtechnologies and systems. Suitable networks for use with the presentvisualization and management systems include any of a wide variety ofphysical infrastructures, protocols, connections, and encryptionalgorithms. According to various embodiments, networking practices maybe implemented in order to comply with accepted healthcare standardsand/or government regulations.

Some viewing levels may include plan map views allowing a user tovisualize navigational paths of a telepresence device on one or morefloors of a healthcare facility. In some embodiments, a user mayvisualize and distinguish between navigational paths in which atelepresence device was in an automated mode and navigational paths inwhich the telepresence device was in a teleoperated mode. Additionally,in one viewing level a user may select (e.g., via a click or amouse-over) a room and view telemetry data associated with a patient inthe selected room for a given time period.

Additionally, various viewing levels may allow a user to selectivelyvisualize and filter data associated with patients, healthcarepractitioners (e.g., a primary physician), and telepresence devicestatistics related to the usage of a telepresence device with respect toa particular patient or by a particular healthcare practitioner. Invarious examples, a coordinate system may be selectively populated withvarious graphs of telepresence device statistics, as described herein.The graphs may be filtered based on various criteria as selected by theuser. The visualization may allow a user to easily and quickly findcorrelations between the manner in which a telepresence device is usedand the outcome of a patient.

Various aspects of this disclosure are also described in U.S. patentapplication Ser. No. 13/444,106, filed Apr. 11, 2012 titled “SYSTEMS ANDMETHODS FOR VISUALIZING AND MANAGING TELEPRESENCE DEVICES IN HEALTHCARENETWORKS,” which application is incorporated herein by reference in itsentirety.

The term “coordinate system” may refer to any type of organized visualor graphical representation of data. For example, a coordinate systemmay comprise, utilize, and/or incorporate a bar graph, a line chart, aplot, a diagram, a pie chart, a number line, a Cartesian coordinatesystem, a histogram, a cylindrical and/or spherical coordinate system, atimeline, a cartogram, a pedigree chart, a bubble chart, a polar areadiagram, a waterfall chart, a tree, a polar coordinate system, amapping, a radar chart, a distribution system, a scattergram, a Ganttchart, a Smith chart, a Nolan chart, a scatterplot, a color-coordinateddata set, and/or other visual representation of data. The term “graph”as used herein may refer to any type of data representation within acoordinate system. For example, a graph may be a line drawn on aCartesian coordinate system, a slice of a pie chart, a point on ascattergram, and/or other data representation on a coordinate system asdefined herein.

Reference throughout this specification to “one embodiment” or “anembodiment” means that a particular feature, structure, orcharacteristic described in connection with the embodiment is includedin at least one embodiment. Thus, the appearances of the phrases “in oneembodiment” and “in an embodiment” in various places throughout thisspecification are not necessarily all referring to the same embodiment.In particular, an “embodiment” may be a system, an article ofmanufacture (such as a computer-readable storage medium), a method,and/or a product of a process.

The phrases “connected to” and “in communication with” refer to any formof interaction between two or more entities, including mechanical,electrical, magnetic, and electromagnetic interaction. Two componentsmay be connected to each other even though they are not in directcontact with each other and even though there may be intermediarydevices between the two components.

The embodiments of the disclosure will be best understood by referenceto the drawings, wherein like elements are designated by like numeralsthroughout. In the following description, numerous specific details areprovided for a thorough understanding of the embodiments describedherein. However, those of skill in the art will recognize that one ormore of the specific details may be omitted, or other methods,components, or materials may be used. In some cases, operations are notshown or described in detail.

Furthermore, the described features, operations, or characteristics maybe combined in any suitable manner in one or more embodiments. The orderof the steps or actions of the methods described in connection with theembodiments disclosed may be varied. Thus, any order in the drawings orDetailed Description is for illustrative purposes only and is not meantto imply a required order, unless otherwise specified.

Embodiments may include various features, which may be embodied inmachine-executable instructions executed by a general-purpose orspecial-purpose computer (or other electronic device). Alternatively,the features may be performed by hardware components that includespecific logic for performing the steps or by a combination of hardware,software, and/or firmware. Accordingly, the various components, modules,systems, and/or features described herein may be embodied as moduleswithin a system. Such a system may be implemented in software, firmware,hardware, and/or physical infrastructure.

Embodiments may also be provided as a computer program product includinga non-transitory machine-readable medium having stored thereoninstructions that may be used to program or be executed on a computer(or other electronic device) to perform processes described herein. Themachine-readable medium may include, but is not limited to, hard drives,floppy diskettes, optical disks, CD-ROMs, DVD-ROMs, ROMs, RAMs, EPROMs,EEPROMs, magnetic or optical cards, solid-state memory devices, or othertypes of media/machine-readable media suitable for storing electronicinstructions.

FIG. 1 illustrates a global viewing level 100 of a geographicalrepresentation of the world 110. As illustrated, the global viewinglevel 100 may include a navigation panel 120 with various iconsconfigured to allow a user to pan, rotate, tilt, and zoom within theglobal viewing level. For instance, a slider bar may be slid between a“−” sign and a “+” sign in order to control the field of view of thegeographical representation 110. A wide field of view may include theentire globe, as illustrated, and a narrow field of view may be limitedto a single telepresence device and/or healthcare facility. The globalviewing level 100 may include various quick links 130. A user may usethe quick links 130 to navigate to a specific location on thegeographical representation 110 and/or automatically adjust the field ofview.

The viewing level 100 may also include a panel 140 of device-type icons.By selecting a device icon in the panel 140, a user may choose whetheror not the particular device type is displayed on the geographicalrepresentation 110. For example, the illustrated viewing level 100displays icons representing various telepresence devices on thegeographical representation 110. By toggling the device-type iconswithin the panel 140, a user may selectively view one or more types oftelepresence devices and disable the display of the other types.Accordingly, a user may filter by telepresence device type.

Additionally, the viewing level 100 may include selectable overlayswithin an overlay panel 150. The selectable overlays may include, butare not limited to, a population density, a stroke frequency, anadoption rate of a software update, an adoption rate of a firmwareupdate, a frequency of a particular medical condition, a frequency of aparticular technical difficulty, an average age of the population, anaverage age of patients, socioeconomic conditions, an availability ofwireless communications, a relative location of medical practitioners,active sessions, a data connection strength, and a relative location ofsupport technicians. The informational overlay may be overlaid on thegeographical representation 110 as a heat map, as graphics, as pictures,as icons, as numbers, and/or as text. A user may apply an overlay on thegeographical representation 110 in order to visualize the relationshipsbetween the information conveyed by the overlay, technical data,healthcare networks, and/or telepresence devices.

A lower panel 160 may include additional selectable icons and/or displayinformation about the current session. For example, a reset icon mayallow a user to reset or refresh the visualization and managementsystem. A customer networks icon may allow the user to switch from ageographical representation of the relative location of telepresencedevices to a geographical representation of the relative location ofhealthcare facilities and/or healthcare networks, or to a connectivitycontrol panel.

For purposes of this disclosure, the selection of an icon within any ofthe panels 130, 140, 150, and 160 may be considered a transition fromthe viewing level 100 to a different viewing level. Alternatively, theselection of some of the icons within the panels 130, 140, 150, and/or160 may display additional information, remove displayed information,and/or modify displayed information but remain within the same viewinglevel. The viewing level 100 illustrated in FIG. 1 may be displayed in aweb browser, potentially using one or more plug-ins. Alternatively, thevarious viewing levels may be displayed and/or controlled in astand-alone application or in any other suitable computing environment.

FIG. 2 illustrates a viewing level 200 with a narrower field of viewshowing a heat map overlaid on a geographical representation 210. Theillustrated geographical representation 210 includes the continentalUnited States. As illustrated, an overlay panel 220 may include variousinformational overlays that may be applied to the geographicalrepresentation 210. The overlays may be applied in any of a wide varietyof manners, such as by applying a corresponding heat map, graphics,pictures, icons, numbers, and/or text. In the illustrated embodiment,the white dots on the geographical representation 210 may representavailable telepresence devices.

The heat map overlay may correspond to a population density.Accordingly, it may be useful (e.g., to assess need or salesopportunities) to compare the population density across the continentalUnited States to the location of available/existing telepresencedevices. For instance, in the illustrated example, the populationdensity near the border of Illinois and Iowa is relative high, and yetthere is no telepresence device nearby. Accordingly, a sales opportunityor need may exist in that region.

FIG. 3 illustrates a “Quick Nav” shortcut menu 310 configured to allowfor direct navigation to a location within the geographicalrepresentation 320. The Quick Nav menu 310 may be customized and/orinclude various default locations. Any number of selectable locationsmay be included in the shortcut menu 310. Selecting a location withinthe shortcut menu 310 may pan, rotate, tilt, and/or zoom the window inorder to frame the selected geographical location. The telepresencedevices and/or healthcare facilities within the framed geographicalrepresentation 320 may be displayed as icons resembling correspondingtypes of telepresence devices and/or healthcare facilities.Alternatively, other symbols, icons, coloring, numbers, text, ormarkings may be utilized to display the relative location of varioustelepresence devices and/or healthcare facilities within the displayedgeographical boundaries. In the illustrated embodiment, roboticallycontrolled telepresence devices are illustrated with robot icon 322, andmobile telepresence units are illustrated with an icon 325 resemblingthe device type.

FIGS. 4A and 4B illustrate context-based detail request menus 400 and450 providing access to specific details based on the type oftelepresence device and/or type of healthcare facility. The detailedinformation, titles, names, and icons used in the menus 400 and 450 maybe modified or adapted for a particular application or need. Asillustrated in FIG. 4A, by right-clicking (or through the use of anothersecondary selection method) on the robot icon, a user may select variousviewing details or management details in the panel 410. Detail requestsmay include information associated with telepresence devices,communication sessions, shipment history, and available networks.Additionally, a user may select various management details, such asconnectivity and support. Different types of telepresence devices mayinclude different detail selection options for viewing and/or managing.Moreover, the identity of the user may modify which selectable detailrequests are available. For example, an administrator of a telepresencedevice may have more access than a low-level healthcare practitioner.

As illustrated in FIG. 4B, when a healthcare facility icon isright-clicked, a different detail request panel 460 may be displayed.The selectable detail requests within the panel 460 may be based on theidentity of the user, a characteristic of the user, the type ofhealthcare facility, and/or the types of available telepresence devicesassociated with the healthcare facility. As illustrated, a user mayselect to view additional details associated with endpoints(telepresence devices) associated with the healthcare facility,connection rules, utilization statistics of telepresence devices,transfer statistics, and other interfacing applications. Additionally,the user may select to manage details such as connectivity, support,and/or a dashboard of other informational details.

Hovering a mouse over a telepresence device icon and/or a healthcarefacility icon (a mouse-over) may display one or more details about thespecific device/facility. For example, a mouse-over may display theserial number of a telepresence device and the hospital with which it isassociated. Additional information may be displayed via a mouse-overand/or by selecting the icon representing the device/facility.

Any of the selectable icons, panels, and/or options may be accessible inany of the viewing levels described herein. Specifically, the viewinglevel requests via navigation panels and/or shortcut menus (illustratedin FIGS. 1 and 3), the available overlays (illustrated in FIG. 2), andthe detail request panels (illustrated in FIGS. 4A and 4B) may beavailable in the viewing level illustrated in FIG. 1. The exactdepictions of icons, panels, geographical representations, and otherspecific details illustrated and/or described in conjunction with thefigures are merely exemplary and may be modified, augmented, replaced,and/or eliminated for a particular application.

FIG. 5 illustrates a viewing level 500 including a session viewer forvisualizing and/or managing sessions and telepresence devices during aselected time period. The session viewer in viewing level 500 may allowa user to visualize data relating to specific remote telepresencesessions on a geographical representation 510. The visualization mayinclude a set of lines or arcs representing the connections. Asillustrated, a time period may be selected in the panel 520, the totalnumber of active sessions may be illustrated in the active sessionspanel 530, and the active telepresence devices (endpoints) may beillustrated in the panel 540. Icons representing various telepresencedevices, healthcare facilities, and/or communication connections may bedisplayed on the geographical representation 510, as illustrated in FIG.5.

In various embodiments, visual attributes and/or text associated withthe communication connections may be indicative of a telepresencesession's quality, control station used, servers used, and/or othersession data. For example, the visual appearance of a communicationconnection may be modified based on the session's quality, the controlstation, which server was used to negotiate the connection, theendpoint, the type of session (peer-to-peer or server-based), and/orother session data. A single session, a set of sessions from multipleendpoint and control station pairs at a single point in time, and/or aset of multiple sessions over a time span specified by the user may alsobe provided in this or another viewing level.

In various embodiments, a viewing level including a session viewer asillustrated in FIG. 5 may allow a user to view the number of activesessions, a list of active telepresence devices, and filtering optionsto limit the types of devices displayed, the connection types, theserver types, the time period, and/or other attributes of telepresencesessions. In some cases, a user may view session data associated with aparticular mobile telepresence unit. The visualization and managementsystem may display a geographical representation bounded by a travelarea of the mobile telepresence unit.

As illustrated in FIG. 6, various overlays may be used in conjunctionwith the session viewer viewing level in order to provide additionalinformation about a particular telepresence session. A viewing level 600may include a route 620 traveled by a mobile telepresence device 625over a given time period. The viewing level 600 may also include robottelepresence devices 630 and 635 with which the mobile telepresencedevice 625 communicated. The relative location of the mobiletelepresence device 625 may move along the route 620 as the time ismoved along the timeline 650 from 4:32 to 5:58 (corresponding to thebeginning and end of one or more telepresence sessions).

An overlay, such as 3G and 4G cellular data availability, may beselected from the panel 610 and overlaid on the geographicalrepresentation of the viewing level 600 in order to provide additionalinformation to the user. The user may diagnose communication problemsand/or improve the overall telepresence session experience using variousinformational overlays. Such a viewing level may be particularly usefulfor visualizing and/or managing the use of mobile telepresence unitstransported in ambulances and/or used remotely by healthcarepractitioners (e.g., while at home or on vacation). For example, whilemonitoring a number of active sessions in a session viewer asillustrated in FIG. 5, a user may see an indication of a connectionproblem associated with a mobile telepresence device. In response, theuser may open a session viewer associated with the mobile telepresencedevice, as illustrated in FIG. 6, and choose to overlay 3G and/or 4Gcellular data availability to investigate and discover possible causesof the connection problem.

As described in conjunction with FIG. 1, a user may select a viewinglevel that displays the relative location of at least one healthcarefacility and its relationships to other healthcare facilities on ageographical representation. FIG. 7A illustrates a hub healthcarefacility, such as a hub hospital, and its relationships with otherhealthcare facilities as arcs extending from the hub healthcare facilityto other related healthcare facilities on a geographical representation.Transitioning to the viewing level 700 may initially remove alltelepresence device icons and display a new set of icons representingeach customer organization. Different icons may be used to representeach type of healthcare facility and/or the capabilities of eachhealthcare facility. Additionally, different icons may be used torepresent various classes of customers, such as hospitals, clinics,corporate headquarters, partner hospitals, and others. Similar to thedescription above, hovering over a customer icon may display theorganization's name and/or some additional information. Clicking on acustomer icon may display all the telepresence devices and/or hospitalsassociated with the customer's network. Animated arcs representing thecurrent connectivity paths may extend from the customer hub orheadquarters to the locations of current telepresence devices.

Additional details about arc connections and/or the hub hospital may bemade available to a user by selecting or mousing over the icons. FIG. 7Billustrates a viewing level 750 including the location andinterconnections of various healthcare facilities in a healthcarenetwork on a geographical representation. Again, context-sensitivedetail requests may be made by mousing over the healthcare facilitiesand/or the connections therebetween.

Additional viewing levels may include menus, icons, and/or otherinformation for visualizing and/or managing the connectivity betweenvarious telepresence devices, healthcare practitioners, healthcarefacilities, and/or healthcare networks. Additionally, details regardinghow and when patients are transferred between various healthcarefacilities may be presented as numerical values, as statistics, asgraphs, and/or geographically on a geographical representation. In someembodiments, specific viewing levels may be available that displaydetails associated with the shipment history of particular devicesand/or software/firmware updates associated with one or moretelepresence devices.

For example, a viewing level may include the shipment history of atelepresence device with respect to a timeline. The location of thetelepresence device may be visualized at each point during the shipmentprocess. Such a viewing level may allow for the optimization oftransportation and shipping of telepresence devices. A viewing level mayalso be configured to illustrate the progress of an automatic softwareupdate from release time to some threshold of acceptance among thetelepresence devices in a particular geographical area. For example, asoftware update is generally released to the entire fleet at a certaintime and date. A telepresence device may be automatically updated whenit connects to the network. The threshold of acceptance may be when 95%of all telepresence devices have reported that the new update has beeninstalled. The viewing level may provide for the visualization of asoftware update on a geographical representation. For example, alltelepresence devices may initially start with a red circle in their iconto show they have not accepted the update. As the user advances a timebar forward from the release date, the telepresence device icons maychange color to show the status of a software update process. This mightbe from red (not installed) to yellow (downloading from a server) togreen (installed). Accordingly, a user may gauge the effectiveness of anautomatic software update system. This visualization tool may allow auser to easily identify areas, or specific telepresence devices, wherethe update process failed or encountered problems.

As illustrated in FIG. 8, a viewing level 800 may display informationassociated with a healthcare network 850 on a geographicalrepresentation 860. A timeline filter may be provided in a panel 820.Viewing level 800 may include an information selection panel 805. Theviewing level 800 allows information from panel 805 that is associatedwith multiple healthcare facilities and/or telepresence devices shown ina key 810 to be visually presented in conjunction with a geographicalrepresentation 860. A user may select between a variety of informationaloverlays, graphs, informational tags, icons, text, numbers, connectionlines, and/or colors to visually convey information related tohealthcare facilities and/or telepresence devices. According to variousembodiments, a user may graphically compare data among spoke healthcarefacilities or between spoke healthcare facilities and a hub healthcarefacility (see the key 810) on the geographical representation 860.

In the illustrated embodiment, stroke information has been selected inthe information selection panel 805. Accordingly, a user may view thenumber of patients who were the subject of a stroke consultation made bya healthcare practitioner in a hub healthcare facility usingtelepresence devices. A user may view the number of such patients whowere determined fit to stay in the rural (spoke) healthcare facilities,and those who were transferred to the more capable hub healthcarefacility. Such a viewing level may allow for a visualization of theeffectiveness and results of consultations via telepresence devices.

The viewing level 800 may allow a user to visualize the value atelepresence system is bringing to a customer's hub hospital and spokehospitals in terms of patients kept and acute cases transferred. Forexample, a rural hospital's administrator may visualize the number ofpatients who were subject to a telepresence consultation performed by aspecialist based in a hub hospital. The rural healthcare facility mayhave a small graph beside it indicating the number of patients keptversus the total number of stroke patients admitted in the selected timeperiod. The healthcare facility may also have an arrow configured with awidth corresponding to the relative number of patients transferred fromthe spoke healthcare facility to the hub healthcare facility.Accordingly, the rural hospital administrator (and the hub hospitaladministrator) may visualize the benefits of the telepresence devicesand telepresence network.

The user may select a different information set from the informationselection panel 805 in order to visualize data relating to a particularfacility or device, or visually compare data between and/or amongvarious spoke and hub healthcare facilities on the geographicalrepresentation 860. Additionally, information directly related to thetelepresence devices may be selected within information selection panel805, in order for a user to visually compare the status of telepresencedevices between spoke healthcare facilities on the geographicalrepresentation 860. Information sets selectable via the informationselection panel 805 may include, but are not limited to, informationrelated to medical condition, such as stroke or heart attack,utilization rates, session quality information, telepresence deviceinformation, support activity, battery levels, last reported time,active session, workflow metrics, available telepresence devices,trained specialists, financial information, subscription information,and/or other information associated with telepresence devices,telepresence networks, healthcare facilities, and/or healthcarenetworks.

FIG. 9 illustrates a viewing level 900 including a dashboard of detailedinformation 920, 930, 940, 950, and 960 associated with one or moretelepresence devices. The displayed details may include variousnumerical information, charts, and/or graphs. The information displayedin the dashboard of information may depend on the types of telepresencedevices, the types of healthcare facilities, and/or the identity of theuser. A navigation bar 910 may allow the user to navigate betweenvarious viewing levels. In the illustrated example, an endpoints panel920 may include details associated with one or more endpoints(telepresence devices) in a healthcare facility. The endpoints panel 920may include real-time information associated with a particulartelepresence device, including, but not limited to, serial number, modelnumber, type, name, battery level, connection status, location, date andtime last reported, available peripherals, and associated applications.

A utilization panel 930 may display details associated with the remotetelepresence sessions for one or more telepresence devices and/or aparticular healthcare facility or network. For example, the utilizationpanel 930 may include details regarding utilization over various timeperiods, a total utilization time, an average session duration, aduration of a particular session, a start time and end time of aparticular session, a Quality of Service (QoS) for one or more sessions,a current available bandwidth, a bandwidth availability with respect totime, a current location of a telepresence device, and historicallocations of a telepresence device with respect to time.

A support panel 950 may display information associated with technicalsupport, software updates, firmware updates, hardwareupdates/replacements, and/or other support issues. The support panel 950may display a list of personnel responsible for a telepresence deviceand/or healthcare facility. Historical data regarding support issues mayalso be available. Automatic and/or manual updates may be applied viasupport panel 950 as well.

An application panel 960 may provide information associated withapplications registered for use with the telepresence device and/orhealthcare facility. Information associated with various workflowapplications, such as StrokeRESPOND described in U.S. patent applicationSer. No. 12/362,454, filed on Jan. 29, 2009, titled “DOCUMENTATIONTHROUGH A REMOTE PRESENCE ROBOT,” which application is herebyincorporated by reference in its entirety, may also be displayed or madeaccessible in application panel 960.

A connection panel 940 may include information associated with networkconnections and maintenance. For instance, the connection panel 940 maydisplay the basic network start and end times and durations of networkconnectivity. The connection panel 940 may include a graphicalrepresentation of network up-time, network down-time, bandwidthavailability, bandwidth use, max ping, average ping, packet loss, and/orother information associated with network connectivity between atelepresence device and a healthcare facility. Network informationassociated with a connection between two healthcare facilities may alsobe displayed and/or managed.

The connection panel 940 may additionally, or alternatively, displayinformation associated with connection services configured to provide areliable and robust peer-to-peer and/or server-based connection across awide range of network types. For instance, the systems and methodsdescribed in U.S. patent application Ser. No. 11/801,491, filed on May9, 2007, titled “ROBOT SYSTEM THAT OPERATES THROUGH A NETWORK FIREWALL,”which application is hereby incorporated by reference in its entirety,may be used in conjunction with the presently described systems andmethods. The connection panel 940 may also display informationassociated with automatic bandwidth tests and/or general profiling of anetwork.

FIG. 10 illustrates a viewing level 1000 displaying the dynamicbandwidth management, latency, and packet loss during various timeperiods for one or more telepresence devices. Such a viewing level 1000may be useful for a user to diagnose networking problems and/or improvea telepresence network.

FIG. 11 illustrates a viewing level 1100 of an application selected viathe application panel 960 in FIG. 9. The exemplary information panelsillustrated in FIG. 11 are associated with the applicationStrokeRESPOND. Any of a wide variety of application interfaces may beaccessible via the visualization and management system described herein.As illustrated, information associated with strokes may be displayed inconjunction with the StrokeRESPOND application. For instance, thedisplay may include a door-to-needle time 1150 corresponding to theamount of time between a patient's arrival at a healthcare facility andthe time the patient receives clot-busting medication. The display mayalso include StrokeRESPOND statistics 1110, physician response times1120, and/or t-PA contraindications and warning information 1140. A usermay navigate to alternative viewing levels and/or return to the previousviewing level via the panel 1130.

FIG. 12 illustrates a viewing level 1200 showing the navigational paths1230 and 1240 of a telepresence device 1210 on a plan map 1260 for aselected time period. According to various embodiments, the viewinglevel 1200 may be selected via the application panel 960 in FIG. 9, fromwithin the detail request panel 460 of FIG. 4B, and/or from within anyother viewing level. The viewing level 1200 may be selected based on aparticular healthcare facility or based on a particular telepresencedevice 1210. In some embodiments, the viewing level 1200 showing thenavigational paths 1230 and 1240 may be an independent program,application, or accessible website.

As illustrated, the plan map 1260 may include various hallways and roomsof a healthcare facility. In some embodiments, the number of rooms,hallways, and/or floors may justify a zoom selection tool, a panningselection tool, and/or a floor selection tool. According to variousembodiments, the plan map 1260 may be displayed along with a time periodselection menu 1220. A user may select a time period via the time periodselection menu 1220. According to various embodiments, the time periodmay range from a few minutes to a few days. In the illustratedembodiment, a user may select a day from a calendar and a time from aslider bar. The user-selected time may constitute a lower bound of aselected time period. The upper bound may also be selected by the user,or, as illustrated, the upper bound may be the current date and time.

Navigational paths 1230 and 1240 of the telepresence device for theselected time period may be displayed on the plan map 1260. Thevisualization tool in viewing level 1200 may provide a user with auseful ability to distinguish between a navigational path 1230 in whichthe telepresence device 1210 was in a teleoperated drive mode, and anavigational path 1240 in which the telepresence device 1210 was in anautonomous drive mode. Additional drive modes, such as a hybrid drivemode, may also be distinguishable on the plan map 1260. Descriptions ofvarious drive modes and systems and methods for implementing the sameare described in U.S. patent application Ser. No. 13/360,579, filed onJan. 27, 2012, titled “INTERFACING WITH A MOBILE TELEPRESENCE ROBOT,”which application is hereby incorporated by reference in its entirety.

In the illustrated embodiments, the navigational path 1230 in which thetelepresence device 1210 was in a teleoperated drive mode is illustratedas a dashed line and the navigational path 1240 in which thetelepresence device 1210 was in an autonomous drive mode is illustratedas a dash-dot-dot line. In practice, the navigational paths 1230 and1240 representing different drive modes may be illustrated on the planmap 1260 as different colors, shades, line patterns, opacities, etc. Inaddition, intersections of multiple types of navigational paths 1230 and1240 may be displayed side-by-side (as illustrated) or as a third linecolor, a particular line shading gradient, a line thickness, a linepattern, or a line hue. For example, if the navigational path 1230 inwhich the telepresence device 1210 was in a teleoperated drive mode isdisplayed as a red line and the navigational path 1240 in which thetelepresence device 1210 was in an autonomous drive mode is illustratedas a blue line, the intersections of the two lines may be illustrated aspurple lines. Such intersections may include long sections of hallwaysor rooms that the telepresence device 1210 traversed in more than onedrive mode.

Additionally, the number of times the telepresence device 1210 traverseda particular section of the plan map 1260 may be displayed as well. Forexample, the thickness of a displayed navigational path may correspondto the number of times the telepresence device 1210 traversed thenavigational path. In other embodiments, the number of times thetelepresence device traversed a particular section of a navigationalpath in a particular drive mode may be visualized using various linecolors, line shading gradients, line color gradients, line thicknesses,line patterns, line hues, numerical annotations, and/or symbolicannotations.

In some embodiments, the current location of the telepresence device1210 may be displayed on the plan map 1260. In other embodiments, thelocation of the telepresence device may be displayed at a selectedinstantaneous time, displayed at an upper or lower bound of a selectedtime period, or selectively removed from display.

FIG. 13 illustrates a viewing level 1300 allowing a user to visualizetelemetry data 1350 for a patient as a pop-up window on a plan map 1360in a selected room 1330. Again, the viewing level 1300 may be selectedvia the application panel 960 in FIG. 9, from within the detail requestpanel 460 of FIG. 4B, and/or from within any other viewing level. Theviewing level 1300 may be selected based on a particular healthcarefacility or based on the telepresence device 1310. In some embodiments,viewing level 1300 may be an independent program, application, oraccessible website.

As illustrated, the plan map 1360 may include various hallways and roomsof a healthcare facility. In some embodiments, the number of rooms,hallways, and/or floors may justify a zoom selection tool, a panningselection tool, and/or a floor selection tool (not illustrated); suchnavigation features may be added as is deemed useful for a particularapplication. According to various embodiments, the plan map 1360 may bedisplayed along with a time period selection menu 1320. A user mayselect a time via the time period selection menu 1320. In theillustrated embodiment, a user may select a day from a calendar and atime from a slider bar. Additionally, a user may select a room withinthe plan map 1360.

Telemetry data 1350 for a patient within the selected room at theselected time may be displayed as a pop-up window (or as a standalonewindow). The telemetry data 1350 may be collected and recorded byvarious monitoring and data collection systems, including thetelepresence device 1310. The telemetry data 1350 may include data suchas blood pressure, heart rate, temperature, respiration rate, andelectrocardiogram information. The displayed telemetry data 1350 may beinstantaneous telemetry data for the selected time. For example, thetelemetry data may be displayed as instantaneous numerical values. Thedisplayed telemetry data 1350 may include waveforms plotted over time.In such an embodiment, the waveform may include, begin with, be centeredon, or end with the selected time.

A user may select a room in any of a wide variety of ways. For example,a user may select a room via a mouse-over 1340 held over the room 1330for a predetermined amount of time. In alternative embodiments, mouseclicks, keyboard inputs, touch inputs, and/or other auxiliary selectioninputs may be used to select a room on the plan map 1360.

In some embodiments, the viewing level 1300 of FIG. 13 and the viewinglevel 1200 of FIG. 12 may be combined into a single viewing level. Insuch an embodiment, a user may selectively view navigational paths of atelepresence device and/or telemetry data associated with a patientwithin a particular room.

FIG. 14 illustrates a table 1400 of patients and various associateddata. Some of the various data points associated with each patient maybe omitted, or additional data points may be included. In someembodiments, the table 1400 may be displayed directly to a user.Visualization of the data in table 1400 may be further enhanced usingthe visualization tools illustrated in FIGS. 15-20. The actual datawithin each category and the number of patients is merely exemplary. Thedata within each category may vary by hospital, by physician(s), bytelepresence device, and/or by individual experiences. Moreover, largerdata sets may more accurately reveal trends in the data. The datacategories are described below from left to right across FIG. 14.

The table 1400 includes a patient identification 1401. The patientidentification may be a name, a number, an alphanumeric string, or apseudonym, and may identify gender, etc. Each patient may be ranked orassigned an outcome rating 1402. The outcome rating may be assignedautomatically based on a predefined set of criteria, or may be input bya nurse, doctor, or other medical practitioner. The outcome rating maybe a daily rating, an average rating for a given time period, or anoutcome rating for a discharged patient. In one example, the outcomerating corresponds to a practitioner-assigned rating given to eachpatient as the patient is discharged. In one embodiment, the outcomerating is a numerical value ranging from 0 (death) to 100 (fullrecovery). Ratings between 0 and 100 may be subjective or objectivelyassigned based on a predetermined set of criteria.

The data may include a primary physician 1403. The primary physician maybe the primary physician assigned to the patient at a time the outcomerating was assigned, or the primary physician of the patient based onthe total amount of time a physician cared for the patient. In someembodiments, a patient may have a local primary physician and a remoteprimary physician. The primary physician 1403 listed on the table 1400may be the physician who most used the telepresence device to treat thepatient. The data may include a primary condition 1404 as well. Theprimary condition 1404 may be a general category describing thecondition for which the patient is being treated. In some embodiments,the patient may have multiple primary conditions 1404.

The data may also include a room number 1405 of the patient and thenumber of visits made each day by a telepresence device 1406.Information about the usage of a telepresence device accessory, such asthe number of times a stethoscope of the telepresence device is used1407, may also be included. Telepresence device accessories may includeany of a wide variety of accessory devices configured to measure aphysiological parameter. Measuring a physiological parameter may includea remote practitioner viewing a sonogram screen as a sonogram device isused on a patient. Additional examples of accessories that may be usedvia a telepresence device include accessories configured to determineblood pressure, heart rate, temperature, respiration rate, andelectrocardiogram information. Any of a wide variety of instruments andvisualization tools may be incorporated as accessories to a telepresencedevice, and the usage of the same may be included as data points in thetable 1400.

Information associated with camera usage may also be included. Forexample, the amount of time a camera of the telepresence device iszoomed to 50% or greater 1408, the amount of time the camera of thetelepresence device is used to look at the patient 1409, the amount oftime the camera of the telepresence device is used to look at staff forthe patient 1410, the amount of time the camera of the telepresencedevice is used to look at a monitor for a patient 1411, and/or theamount of time the camera of the telepresence device is used to look atcharts for the patient 1412 may be included in table 1400. The data mayalso include the amount of time the camera of the telepresence device isused to look at other things 1413. Whether the camera of thetelepresence device is being used to look at a patient, a family member,staff, charts, monitors, or other things could be determined using oneor more image analysis or computer vision techniques. For example, thisfunctionality could be accomplished using Haar-like feature detection toidentify faces. Patients, who may be in a prostrate position, may bedistinguished from family and staff using height or skeletal mapping toidentify probable body position. Additionally, feature detectionalgorithms such as scale-invariant feature transform (SIFT) may be usedto identify hospital attire for distinguishing hospital personnel.SIFT-based feature detection may also be used to identify screens andcharts.

The data may also include the amount of time the telepresence device isin the room of the patient 1414, the amount of time the telepresencedevice is at the bedside of the patient 1415, and/or the amount of timethe telepresence device spends driving 1416. This data may be filteredsuch that the amount of time the telepresence device is in the room doesnot include the amount of time the telepresence device is at thepatient's bedside, even though the telepresence device was necessarilywithin the patient's room when it was at the patient's bedside.

An analysis of the data above may also enable a user to discover usagetrends for a telepresence device that result in the most positiveoutcome ratings. For example, it may be discovered that the number ofvisits by a telepresence device per day correlates to positive patientratings. The following description of FIGS. 15-20 illustrates variousexamples of potential visualization parameters that allow for the dataof numerous patients to be visually presented in a useful manner to auser. It may be appreciated that an exhaustive table of thousands ofpatients may be difficult for a user to process. However, a graphicalvisualization tool may allow a user to quickly discover correlations andassociations between the usage of a telepresence device and patientwell-being.

FIG. 15 illustrates a coordinate system 1510 including selected graphs1520 of patient outcome ratings and various telepresence devicestatistics associated with the patients. As illustrated, the viewinglevel 1500 includes the coordinate system 1510, with various graphs1520, and a legend 1530. The horizontal axis of each of the coordinatesystems in FIGS. 15-20 is labeled with the identification numbers ofeach of a plurality of patients. Accordingly, graphs 1520 are graphedwith respect to each patient. In some embodiments, the graphs may begraphed as scatterplots, accurately reflecting the discrete number ofpatients. In other embodiments, line graphs may be extrapolated from theavailable data, and/or another type of graph, such as a bar graph, maybe utilized. Viewing level 1500 may further include a telepresencedevice statistic selection panel 1540 allowing a user to selectivelydisplay graphs for any number of telepresence device statistics.

The telepresence device statistics may include any of a wide variety ofinformational data associated with the usage of a telepresence devicefor a particular patient. In the illustrated embodiments, the selectabletelepresence device statistics include (from top to bottom) the numberof visits made by the telepresence device per day, the number ofstethoscope usages during a certain time period (it may be the entiretime the patient was being treated), the amount of time a camera of thetelepresence device is zoomed to 50% or more, the amount of time thecamera of the telepresence device is used to look at a patient, theamount of time the camera of the telepresence device is used to look atstaff, the amount of time the camera of the telepresence device is usedto look at monitors or charts, the amount of time the telepresencedevice is in the patient's room, the amount of time the telepresencedevice is at the patient's bedside, and the amount of time thetelepresence device is driving for the patient. Additional telepresencedevice statistics may be included in the telepresence device statisticselection panel 1540, and/or some of the listed statistics may beomitted. Similar abbreviations for the various telepresence devicestatistics 1540 are used throughout FIGS. 15-20. A filter selectionpanel 1550 is set to “all” in FIG. 15.

FIG. 15 illustrates a coordinate system 1510 including selected graphs1520 corresponding to the checked boxes in the telepresence devicestatistic selection panel 1540. The graphs 1520 indicate that the amountof time a camera of a telepresence device is used to look atmonitors/charts may correspond to the outcome ranking of a patient. Itwill be appreciated that similar data in a table form may be difficultto analyze for a user, while the visualization techniques and toolsdescribed herein may facilitate rapid and improved data analysis in aselective graphical form.

FIG. 16 illustrates viewing level 1600 including a coordinate system1610 with a number of selected graphs 1620, including an outcome ratingfor each patient, the number of visits by a telepresence device each dayto each patient, and the number of stethoscope usages for each patient.A legend 1630 may facilitate review of the coordinate system 1610. Inthe illustrated examples, graphs 1620 are distinguishable based ondifferent line patterns (dashes). In practice, each graph 1620 may bedistinguishable using various line colors, line shading gradients, linecolor gradients, line thicknesses, line patterns, line hues, numericalannotations, and/or symbolic annotations.

The graphs 1620 may indicate that the number of visits per day by atelepresence device may positively correspond to an outcome rating of apatient. A user may visualize the coordinate system 1610 and determinethat a telepresence device should visit each patient more frequently.The viewing level 1600 includes only the number of visits per day andthe number of stethoscope usages selected via telepresence devicestatistic selection panel 1640. The viewing level 1600 does not includeany filtering via filter selection panel 1650.

FIG. 17 illustrates a viewing level 1700 including a coordinate system1710 with graphs 1720 of patient outcome ratings, a number of visits perday, and a number of stethoscope uses, as can be seen in legend 1730.Accordingly, the graphs 1720 of FIG. 17 are the same as in FIG. 16;i.e., the selections made via telepresence device statistic selectionpanels 1740 and 1640 are the same. However, in FIG. 17, a conditionfilter is applied via filter selection panel 1750. The graphs 1720 ofFIG. 17 are filtered to include only the data for patients whose primarycondition is respiratory in nature.

Comparing FIGS. 16 and 17, it can be seen that the number of stethoscopeuses in with patients whose primary condition is respiratory in naturecorrelates with the outcome ratings (FIG. 17), while the number ofstethoscope uses in patients with all types of conditions (unfiltered)does not correlate with the outcome ratings (FIG. 16). Accordingly, itmay be useful to adjust the condition, primary physician, and roomnumber filters available in filter selection panel 1750 in order tofacilitate the discovery of additional correlations within the datasets.

FIG. 18A illustrates a viewing level 1800 including a coordinate system1810 with graphs 1820. Graphs 1820 include an outcome rating and theamount of time a camera of a telepresence device is zoomed greater than50%, as illustrated in the legend 1830. The filters in filter selectionpanel 1850 are set to “all.” As can be seen in FIG. 18A, there does notseem to be a correlation between the amount of time the camera of thetelepresence device is zoomed greater than 50% and the outcome rating ofthe patient.

However, looking at FIG. 18B, it can be seen that by applying acondition filter within the filter selection panel 1850 to visualizeonly those patients whose primary condition is neurological in nature, acorrelation between camera usage and outcome rating can be seen.Accordingly, graphs 1821 illustrate that for patients with neurologicalconditions, using the camera of a telepresence device zoomed to 50% orgreater is correlated to the outcome rating of the patient.

FIG. 19 illustrates a viewing level 1900 with a coordinate system 1910that includes numerous graphs 1920 selected via the telepresence devicestatistic selection panel 1940. Each of the graphs 1920 is described inthe legend 1930. A physician filter may be applied via the filterselection panel 1950. Accordingly, data associated with a particularphysician is graphed. An unfiltered visibility slider 1980 may allow thecomplete set of data to be partially visible. This may allow a user tovisualize the data of a particular physician with respect to all otherphysicians. Accordingly, graphs 1920 include data associated with theselected physician in bold, and the complete set of data in a thinnerline. The same line pattern (dashes) is used for each telepresencedevice statistic. In various embodiments, the unfiltered visibilityslider 1980 may allow a user to select an opacity percentage between 0and 100. The graphs 1920 may be distinguishable using various linecolors, line shading gradients, line color gradients, line thicknesses,line patterns, line hues, numerical annotations, and/or symbolicannotations.

FIG. 20 illustrates a viewing level 2000 with a coordinate system 2010that includes numerous graphs 2020 selected via the telepresence devicestatistic selection panel 2040. Each of the graphs 2020 may be describedin the legend 2030. A room number filter may be applied via the filterselection panel 2050. Accordingly, data associated with patients whostayed in a particular room is graphed in graphs 2020. An unfilteredvisibility slider 2080 may allow data for the selected room to becompared with that of all of the rooms, with the data associated withall of the rooms shown as slightly translucent, with thinner lines, withdifferent hues, and/or the like. Such a viewing level 2000 may allow auser to determine which rooms have the highest success rate. It may bethat rooms closest to a docking station of a telepresence device have ahigher rate of visits by the telepresence device and, accordingly, ahigher outcome rating. The presently described visualization tool mayallow a user to quickly and easily filter, organize, and selectivelydisplay numerous data points in order to determine correlations that mayimprove overall medical care in a healthcare facility.

FIG. 21 illustrates a functional block diagram of a computer system 2100including various modules 2170 for a telepresence network visualizationand management system. As illustrated, computer system 2100 may includea processor 2130, memory (such as RAM) 2140, and a network interface2150 connected via a bus 2120. The bus 2120 may also connect acomputer-readable storage medium 2170. The computer-readable storagemedium 2170 may include various modules, such as a display module 2180,a viewing level request module 2182, a navigation request module 2184, adevice detail request module 2186, a connection rule module 2188, and ahealthcare network detail request module 2190. Additional modules may beincluded, or some modules may be omitted, in order for a computer systemto perform any of the server-side or client-side functions of thevarious systems and methods described herein.

The display module 2180 may be configured to display a viewing level ofa telepresence network on a geographical representation. Display module2180 may be configured to display any of the various viewing levelsdescribed herein, including the various selection panels, filteringpanels, and graphical representations. The viewing level request module2182 may be configured to receive a viewing request to cause the displaymodule 2180 to provide a second viewing level. The navigation requestmodule 2184 may be configured to receive a navigational request tonavigate within the geographical representation.

The device detail request module 2186 may be configured to receive adetail request to cause the display module 2180 to display a thirdviewing level, the third viewing level including information associatedwith one or more telepresence devices. The connection rule module 2188may be configured to allow for the management of a connection rulegoverning telepresence devices. The healthcare network detail requestmodule 2190 may be configured to receive a healthcare network detailrequest to cause the display module 2180 to display a fourth viewinglevel, the fourth viewing level including information associated withhealthcare facilities.

A navigation path display module 2192 may be configured to displaynavigational paths traversed by a telepresence device on a plan map. Thenavigational paths may be displayed in such a way that they aredistinguishable based on drive mode, as described herein. A timeselection module 2194 may be configured to allow a user to specify atime or time period. The time selection module 2194 may receive userinput via a calendar, a clock, a slider, numerical inputs, and/or thelike. A telemetry display module 2196 may be configured to displayhistorical and/or current telemetry data for a selected time or timeperiod for a selected room on a plan map.

A graphing, selection, and filtering module 2198 may be configured toprovide graphical views and receive selection inputs and filteringinputs as described in conjunction with FIGS. 14-20. The graphs producedby graphing, selection, and filtering module 2198 may be locallyrendered or remotely rendered, and may be stored in memory 2140 orrendered in real-time by processor 2130 or another processor (such as aspecialized processor). Any of the described viewing levels,communications systems, inputs, and modules may be implemented in anycombination of hardware, firmware, and software. Moreover, one or morefunctions may be performed remotely or stored remotely as is founduseful.

Many changes may be made to the details of the above-describedembodiments without departing from the underlying principles and scopeof the present disclosure. Accordingly, the scope of the presentlydescribed systems and methods should be determined only by the followingclaims.

What is claimed:
 1. A computer program product, comprising anon-transitory computer-readable medium having executable computerprogram code, the computer program code configured to cause a computerto: display a plan map viewing level of at least a portion of afacility; display a time period selection menu; receive an inputindicating a selected time period; and display a first navigational pathtraversed by a telepresence device while in a first drive mode duringthe selected time period.
 2. The computer program product of claim 1,wherein the computer program code is further configured to cause thecomputer to: display a second navigational path traversed by thetelepresence device while in a second drive mode during the selectedtime period, and wherein the first navigational path is displayed suchthat it is distinguishable from the second navigational path.
 3. Thecomputer program product of claim 1, wherein the first drive modecomprises one of a teleoperated drive mode and an autonomous drive mode.4. The computer program product of claim 2, wherein the first drive modecomprises a teleoperated drive mode and the second drive mode comprisesan autonomous drive mode.
 5. The computer program product of claim 1,wherein receiving the input indicating the selected time periodcomprises receiving a selection of one of a lower bound of the selectedtime period and an upper bound of the selected time period.
 6. Thecomputer program product of claim 1, wherein the computer program codeis further configured to cause a computer to display a historicallocation of the telepresence device at an instantaneous time.
 7. Thecomputer program product of claim 1, wherein the computer program codeis further configured to cause a computer to display a current locationof the telepresence device.
 8. The computer program product of claim 1,wherein the facility comprises a healthcare facility.
 9. The computerprogram product of claim 2, wherein the first navigational path isdisplayed as a first line having one of a first color and a firstpattern, and wherein the second navigational path is displayed as asecond line having at least one of a second color and a second pattern.10. The computer program product of claim 1, wherein the computerprogram code is configured to cause a computer to display the firstnavigational path with a path characteristic corresponding to a numberof times the telepresence device traversed at least one section of thefirst navigational path in the first drive mode during the selected timeperiod.
 11. The computer program product of claim 1, wherein thecomputer program code is further configured to: receive an inputindicating a selected room; and display historical telemetry data of apatient associated with the selected room at the selected time period.12. A computer program product, comprising a non-transitorycomputer-readable medium having executable computer program code, thecomputer program code configured to cause a computer to: display a planmap viewing level of at least a portion of a healthcare facility, thehealthcare facility comprising a plurality of rooms; display a timeselection menu; receive an input indicating a selected time; receive aninput indicating a selected room; receive historical telemetry dataassociated with at least one patient for each of the plurality of rooms;and display historical telemetry data of a patient associated with theselected room at the selected time.
 13. The computer program product ofclaim 122, wherein the historical telemetry data was obtained by atelepresence device.
 14. The computer program product of claim 12,wherein the historical telemetry data comprises one of a blood pressure,a heart rate, a temperature, a respiration rate, and anelectrocardiogram.
 15. The computer program product of claim 12, whereindisplaying historical telemetry data at the selected time comprisesdisplaying instantaneous telemetry data at the selected time.
 16. Thecomputer program product of claim 12, wherein displaying historicaltelemetry data at the selected time comprises displaying instantaneoustelemetry data as numerical values at the selected time.
 17. Thecomputer program product of claim 12, wherein displaying historicaltelemetry data at the selected time comprises displaying telemetry dataas a waveform for a time period that includes the selected time betweena lower time bound and an upper time bound, inclusive.
 18. The computerprogram product of claim 12, wherein the computer program code isfurther configured to cause the computer to display a current locationof a telepresence robot on the plan map.
 19. The computer programproduct of claim 12, wherein the selected time comprises a selected timeperiod, and wherein receiving an input indicating the selected timeperiod comprises receiving an input indicating a lower bound of theselected time period and an upper bound of the selected time period. 20.The computer program product of claim 19, wherein the computer programcode is further configured to cause the computer to: display a firstnavigational path traversed by a telepresence device while in a firstdrive mode during the selected time period; and display a secondnavigational path traversed by the telepresence device while in a seconddrive mode during the selected time period, and wherein the firstnavigational path is displayed such that it is distinguishable from thesecond navigational path.
 21. A computer program product, comprising anon-transitory computer-readable medium having executable computerprogram code, the computer program code configured to cause a computerto: receive a plurality of telepresence device statistics, eachtelepresence device statistic comprising information associated with anaction performed via the telepresence device with respect to each of aplurality of patients; display a telepresence device statistic selectionpanel configured to allow a user to select one or more of the pluralityof telepresence device statistics; receive a selection of at least onetelepresence device statistic via the telepresence device statisticselection panel; and display a visual representation of the selected atleast one telepresence device statistic.
 22. The computer programproduct of claim 1, the computer program code is further configured tocause the computer to: receive a rating for each of the plurality ofpatients treated via a telepresence device, the ratings associated witha health aspect of each of the plurality of patients; and wherein todisplay the visual representation the computer program code is furtherconfigured to cause the computer to: display a graph of the at least oneselected telepresence device statistic with respect to each of theplurality of patients on a coordinate system; and display an indicationof the rating for each of the plurality of patients with respect to eachof the plurality of patients displayed on the coordinate system.
 23. Thecomputer program product of claim 22, wherein the rating for each of theplurality of patients comprises an outcome rating corresponding to ahealth aspect of a discharged patient.
 24. The computer program productof claim 1, wherein the computer program code is further configured tocause a computer to: receive a primary patient condition for each of theplurality of patients; display a filter selection panel comprising acondition filter input, the condition filter input configured to allow auser to select one or more primary patient conditions; receive at leastone selection via the filter selection panel; remove from visualrepresentation any telepresence device statistic not associated with theselections made via the filter selection panel; and update the visualrepresentation of the at least one selected telepresence devicestatistic based on the selections made via the filter selection panel.25. The computer program product of claim 1, wherein the computerprogram code is further configured to cause a computer to: receiveinformation identifying a primary physician for each of the plurality ofpatients; display a filter selection panel comprising a primaryphysician filter input, the primary physician filter input configured toallow a user to select one or more primary physicians; receive at leastone selection via the filter selection panel; remove from the visualrepresentation any of the telepresence device statistics not associatedwith the at least one selection made via the filter selection panel; andupdate the visual representation of the at least one selectedtelepresence device statistic based on the selections made via thefilter selection panel.
 26. The computer program product of claim 1,wherein the computer program code is further configured to cause acomputer to: receive information identifying a room associated with eachof the plurality of patients; display a filter selection panelcomprising a room filter input, the room filter input configured toallow a user to select one or more rooms of a healthcare facility;receive at least one selection via the filter selection panel; removefrom the visual representation any of the plurality of patients notassociated with the at least one selection made via the filter selectionpanel; and update the visual representation of the at least one selectedtelepresence device statistic based on the selections made via thefilter selection panel.
 27. The computer program product of claim 1,wherein the plurality of telepresence device statistics comprises atelepresence device statistic indicating how many visits were made toeach of the plurality of patients by the telepresence device during atime period.
 28. The computer program product of claim 1, wherein theplurality of telepresence device statistics comprises a telepresencedevice statistic associated with a usage of a telepresence deviceaccessory on each of the plurality of patients during a time period, thetelepresence device statistic configured to measure a physiologicalparameter.
 29. The computer program product of claim 28, wherein thetelepresence device accessory is configured to determine one of a bloodpressure, a heart rate, a temperature, a respiration rate, andelectrocardiogram information.
 30. The computer program product of claim28, wherein the telepresence device accessory comprises one of astethoscope, an otoscope, and a medical imaging device.
 31. The computerprogram product of claim 1, wherein the plurality of telepresence devicestatistics comprises a telepresence device statistic associated with ausage of a camera of the telepresence device during a time period. 32.The computer program product of claim 1, wherein the plurality oftelepresence device statistics comprises a telepresence device statisticassociated with a location of the telepresence device relative to eachof the plurality of patients during a time period.